| blob | 4228e0d6ebd7a015bcbae04ee401f1d967c17c56 |
1 /* Dataflow support routines.
2 Copyright (C) 1999, 2000, 2001, 2002 Free Software Foundation, Inc.
3 Contributed by Michael P. Hayes (m.hayes@elec.canterbury.ac.nz,
4 mhayes@redhat.com)
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under
9 the terms of the GNU General Public License as published by the Free
10 Software Foundation; either version 2, or (at your option) any later
11 version.
13 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14 WARRANTY; without even the implied warranty of MERCHANTABILITY or
15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
16 for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING. If not, write to the Free
20 Software Foundation, 59 Temple Place - Suite 330, Boston, MA
21 02111-1307, USA.
24 OVERVIEW:
26 This file provides some dataflow routines for computing reaching defs,
27 upward exposed uses, live variables, def-use chains, and use-def
28 chains. The global dataflow is performed using simple iterative
29 methods with a worklist and could be sped up by ordering the blocks
30 with a depth first search order.
32 A `struct ref' data structure (ref) is allocated for every register
33 reference (def or use) and this records the insn and bb the ref is
34 found within. The refs are linked together in chains of uses and defs
35 for each insn and for each register. Each ref also has a chain field
36 that links all the use refs for a def or all the def refs for a use.
37 This is used to create use-def or def-use chains.
40 USAGE:
42 Here's an example of using the dataflow routines.
44 struct df *df;
46 df = df_init ();
48 df_analyse (df, 0, DF_ALL);
50 df_dump (df, DF_ALL, stderr);
52 df_finish (df);
55 df_init simply creates a poor man's object (df) that needs to be
56 passed to all the dataflow routines. df_finish destroys this
57 object and frees up any allocated memory.
59 df_analyse performs the following:
61 1. Records defs and uses by scanning the insns in each basic block
62 or by scanning the insns queued by df_insn_modify.
63 2. Links defs and uses into insn-def and insn-use chains.
64 3. Links defs and uses into reg-def and reg-use chains.
65 4. Assigns LUIDs to each insn (for modified blocks).
66 5. Calculates local reaching definitions.
67 6. Calculates global reaching definitions.
68 7. Creates use-def chains.
69 8. Calculates local reaching uses (upwards exposed uses).
70 9. Calculates global reaching uses.
71 10. Creates def-use chains.
72 11. Calculates local live registers.
73 12. Calculates global live registers.
74 13. Calculates register lifetimes and determines local registers.
77 PHILOSOPHY:
79 Note that the dataflow information is not updated for every newly
80 deleted or created insn. If the dataflow information requires
81 updating then all the changed, new, or deleted insns needs to be
82 marked with df_insn_modify (or df_insns_modify) either directly or
83 indirectly (say through calling df_insn_delete). df_insn_modify
84 marks all the modified insns to get processed the next time df_analyse
85 is called.
87 Beware that tinkering with insns may invalidate the dataflow information.
88 The philosophy behind these routines is that once the dataflow
89 information has been gathered, the user should store what they require
90 before they tinker with any insn. Once a reg is replaced, for example,
91 then the reg-def/reg-use chains will point to the wrong place. Once a
92 whole lot of changes have been made, df_analyse can be called again
93 to update the dataflow information. Currently, this is not very smart
94 with regard to propagating changes to the dataflow so it should not
95 be called very often.
98 DATA STRUCTURES:
100 The basic object is a REF (reference) and this may either be a DEF
101 (definition) or a USE of a register.
103 These are linked into a variety of lists; namely reg-def, reg-use,
104 insn-def, insn-use, def-use, and use-def lists. For example,
105 the reg-def lists contain all the refs that define a given register
106 while the insn-use lists contain all the refs used by an insn.
108 Note that the reg-def and reg-use chains are generally short (except for the
109 hard registers) and thus it is much faster to search these chains
110 rather than searching the def or use bitmaps.
112 If the insns are in SSA form then the reg-def and use-def lists
113 should only contain the single defining ref.
115 TODO:
117 1) Incremental dataflow analysis.
119 Note that if a loop invariant insn is hoisted (or sunk), we do not
120 need to change the def-use or use-def chains. All we have to do is to
121 change the bb field for all the associated defs and uses and to
122 renumber the LUIDs for the original and new basic blocks of the insn.
124 When shadowing loop mems we create new uses and defs for new pseudos
125 so we do not affect the existing dataflow information.
127 My current strategy is to queue up all modified, created, or deleted
128 insns so when df_analyse is called we can easily determine all the new
129 or deleted refs. Currently the global dataflow information is
130 recomputed from scratch but this could be propagated more efficiently.
132 2) Improved global data flow computation using depth first search.
134 3) Reduced memory requirements.
136 We could operate a pool of ref structures. When a ref is deleted it
137 gets returned to the pool (say by linking on to a chain of free refs).
138 This will require a pair of bitmaps for defs and uses so that we can
139 tell which ones have been changed. Alternatively, we could
140 periodically squeeze the def and use tables and associated bitmaps and
141 renumber the def and use ids.
143 4) Ordering of reg-def and reg-use lists.
145 Should the first entry in the def list be the first def (within a BB)?
146 Similarly, should the first entry in the use list be the last use
147 (within a BB)?
149 5) Working with a sub-CFG.
151 Often the whole CFG does not need to be analysed, for example,
152 when optimising a loop, only certain registers are of interest.
153 Perhaps there should be a bitmap argument to df_analyse to specify
154 which registers should be analysed? */
172 #define FOR_EACH_BB_IN_BITMAP(BITMAP, MIN, BB, CODE) \
173 do \
174 { \
175 unsigned int node_; \
176 EXECUTE_IF_SET_IN_BITMAP (BITMAP, MIN, node_, \
177 {(BB) = BASIC_BLOCK (node_); CODE;}); \
178 } \
179 while (0)
185 #if 0
187 #endif
203 #if 0
206 #endif
268 basic_block,
271 basic_block,
287 transfer_function_bitmap,
292 transfer_function_sbitmap,
296 \f
297 /* Local memory allocation/deallocation routines. */
300 /* Increase the insn info table to have space for at least SIZE + 1
301 elements. */
302 static void
306 {
307 size++;
311 /* Make the table a little larger than requested, so we don't need
312 to enlarge it so often. */
324 {
327 }
328 }
331 /* Increase the reg info table by SIZE more elements. */
332 static void
336 {
337 /* Make table 25 percent larger by default. */
348 /* Zero the new entries. */
353 }
356 #if 0
357 /* Not currently used. */
358 static void
362 {
366 /* Make table 25 percent larger by default. */
374 /* Allocate a new block of memory and link into list of blocks
375 that will need to be freed later. */
379 /* Link all the new refs together, overloading the chain field. */
383 }
384 #endif
388 /* Allocate bitmaps for each basic block. */
389 static void
393 {
395 basic_block bb;
397 /* Free the bitmaps if they need resizing. */
412 {
416 {
417 /* Allocate bitmaps for reaching definitions. */
425 }
428 {
429 /* Allocate bitmaps for upward exposed uses. */
432 /* Note the lack of symmetry. */
438 }
441 {
442 /* Allocate bitmaps for live variables. */
450 }
451 }
452 }
455 /* Free bitmaps for each basic block. */
456 static void
460 {
461 basic_block bb;
464 {
471 {
472 /* Free bitmaps for reaching definitions. */
481 }
484 {
485 /* Free bitmaps for upward exposed uses. */
494 }
497 {
498 /* Free bitmaps for live variables. */
507 }
508 }
510 }
513 /* Allocate and initialize dataflow memory. */
514 static void
518 {
520 basic_block bb;
524 /* Perhaps we should use LUIDs to save memory for the insn_refs
525 table. This is only a small saving; a few pointers. */
530 /* Approximate number of defs by number of insns. */
536 /* Approximate number of uses by twice number of insns. */
543 /* Allocate temporary working array used during local dataflow analysis. */
560 }
563 /* Free all the dataflow info. */
564 static void
567 {
608 }
609 \f
610 /* Local miscellaneous routines. */
612 /* Return a USE for register REGNO. */
615 {
616 rtx reg;
617 rtx use;
623 }
626 /* Return a CLOBBER for register REGNO. */
629 {
630 rtx reg;
631 rtx use;
637 }
638 \f
639 /* Local chain manipulation routines. */
641 /* Create a link in a def-use or use-def chain. */
646 {
654 }
657 /* Add REF to chain head pointed to by PHEAD. */
662 {
666 {
668 {
669 /* Only a single ref. It must be the one we want.
670 If not, the def-use and use-def chains are likely to
671 be inconsistent. */
674 /* Now have an empty chain. */
676 }
677 else
678 {
679 /* Multiple refs. One of them must be us. */
682 else
683 {
684 /* Follow chain. */
686 {
688 {
689 /* Unlink from list. */
692 }
693 }
694 }
695 }
696 }
698 }
701 /* Unlink REF from all def-use/use-def chains, etc. */
702 int
706 {
708 {
711 }
712 else
713 {
716 }
718 }
721 /* Unlink DEF from use-def and reg-def chains. */
722 static void
726 {
730 /* Follow def-use chain to find all the uses of this def. */
732 {
735 /* Unlink this def from the use-def chain. */
737 }
740 /* Unlink def from reg-def chain. */
744 }
747 /* Unlink use from def-use and reg-use chains. */
748 static void
752 {
756 /* Follow use-def chain to find all the defs of this use. */
758 {
761 /* Unlink this use from the def-use chain. */
763 }
766 /* Unlink use from reg-use chain. */
770 }
771 \f
772 /* Local routines for recording refs. */
775 /* Create a new ref of type DF_REF_TYPE for register REG at address
776 LOC within INSN of BB. */
780 rtx reg;
782 rtx insn;
785 {
800 {
802 {
803 /* Make table 25 percent larger. */
807 }
810 }
811 else
812 {
814 {
815 /* Make table 25 percent larger. */
819 }
822 }
824 }
827 /* Create a new reference of type DF_REF_TYPE for a single register REG,
828 used inside the LOC rtx of INSN. */
829 static void
832 rtx reg;
834 rtx insn;
837 {
839 }
842 /* Create new references of type DF_REF_TYPE for each part of register REG
843 at address LOC within INSN of BB. */
844 static void
847 rtx reg;
849 rtx insn;
852 {
858 /* For the reg allocator we are interested in some SUBREG rtx's, but not
859 all. Notably only those representing a word extraction from a multi-word
860 reg. As written in the docu those should have the form
861 (subreg:SI (reg:M A) N), with size(SImode) > size(Mmode).
862 XXX Is that true? We could also use the global word_mode variable. */
867 {
870 }
874 {
881 /* GET_MODE (reg) is correct here. We don't want to go into a SUBREG
882 for the mode, because we only want to add references to regs, which
883 are really referenced. E.g. a (subreg:SI (reg:DI 0) 0) does _not_
884 reference the whole reg 0 in DI mode (which would also include
885 reg 1, at least, if 0 and 1 are SImode registers). */
895 }
896 else
897 {
899 }
900 }
902 /* Writes to paradoxical subregs, or subregs which are too narrow
903 are read-modify-write. */
907 rtx x;
908 {
921 }
923 /* Process all the registers defined in the rtx, X. */
924 static void
927 rtx x;
928 basic_block bb;
929 rtx insn;
930 {
935 /* Some targets place small structures in registers for
936 return values of functions. */
938 {
944 }
946 #ifdef CLASS_CANNOT_CHANGE_MODE
951 #endif
953 /* May be, we should flag the use of strict_low_part somehow. Might be
954 handy for the reg allocator. */
959 {
960 /* Strict low part always contains SUBREG, but we don't want to make
961 it appear outside, as whole register is always considered. */
963 {
966 }
967 #ifdef CLASS_CANNOT_CHANGE_MODE
972 #endif
976 }
981 }
984 /* Process all the registers defined in the pattern rtx, X. */
985 static void
988 rtx x;
989 basic_block bb;
990 rtx insn;
991 {
995 {
996 /* Mark the single def within the pattern. */
998 }
1000 {
1003 /* Mark the multiple defs within the pattern. */
1005 {
1009 }
1010 }
1011 }
1014 /* Process all the registers used in the rtx at address LOC. */
1015 static void
1020 basic_block bb;
1021 rtx insn;
1023 {
1024 RTX_CODE code;
1025 rtx x;
1026 retry:
1032 {
1045 /* If we are clobbering a MEM, mark any registers inside the address
1046 as being used. */
1051 /* If we're clobbering a REG then we have a def so ignore. */
1059 /* While we're here, optimize this case. */
1061 /* In case the SUBREG is not of a register, don't optimize. */
1063 {
1067 }
1068 #ifdef CLASS_CANNOT_CHANGE_MODE
1072 #endif
1074 /* ... Fall through ... */
1077 /* See a register (or subreg) other than being set. */
1082 {
1088 {
1092 {
1094 #ifdef CLASS_CANNOT_CHANGE_MODE
1098 #endif
1102 }
1103 /* ... FALLTHRU ... */
1110 DF_REF_REG_MEM_STORE,
1114 /* A strict_low_part uses the whole reg not only the subreg. */
1119 #ifdef CLASS_CANNOT_CHANGE_MODE
1123 #endif
1130 DF_REF_READ_WRITE);
1137 }
1139 }
1148 {
1149 /* Traditional and volatile asm instructions must be considered to use
1150 and clobber all hard registers, all pseudo-registers and all of
1151 memory. So must TRAP_IF and UNSPEC_VOLATILE operations.
1153 Consider for instance a volatile asm that changes the fpu rounding
1154 mode. An insn should not be moved across this even if it only uses
1155 pseudo-regs because it might give an incorrectly rounded result.
1157 For now, just mark any regs we can find in ASM_OPERANDS as
1158 used. */
1160 /* For all ASM_OPERANDS, we must traverse the vector of input operands.
1161 We can not just fall through here since then we would be confused
1162 by the ASM_INPUT rtx inside ASM_OPERANDS, which do not indicate
1163 traditional asms unlike their normal usage. */
1165 {
1172 }
1174 }
1182 /* Catch the def of the register being modified. */
1185 /* ... Fall through to handle uses ... */
1189 }
1191 /* Recursively scan the operands of this expression. */
1192 {
1197 {
1199 {
1200 /* Tail recursive case: save a function call level. */
1202 {
1205 }
1207 }
1209 {
1214 }
1215 }
1216 }
1217 }
1220 /* Record all the df within INSN of basic block BB. */
1221 static void
1224 basic_block bb;
1225 rtx insn;
1226 {
1230 {
1231 rtx note;
1233 /* Record register defs */
1239 {
1241 {
1248 }
1249 }
1252 {
1253 rtx note;
1254 rtx x;
1256 /* Record the registers used to pass arguments. */
1259 {
1263 }
1265 /* The stack ptr is used (honorarily) by a CALL insn. */
1270 {
1271 /* Calls may also reference any of the global registers,
1272 so they are recorded as used. */
1275 {
1279 }
1280 }
1281 }
1283 /* Record the register uses. */
1289 {
1290 rtx note;
1293 {
1294 /* Kill all registers invalidated by a call. */
1297 {
1300 }
1301 }
1303 /* There may be extra registers to be clobbered. */
1305 note;
1309 }
1310 }
1311 }
1314 /* Record all the refs within the basic block BB. */
1315 static void
1318 basic_block bb;
1319 {
1320 rtx insn;
1322 /* Scan the block an insn at a time from beginning to end. */
1324 {
1326 {
1327 /* Record defs within INSN. */
1329 }
1332 }
1333 }
1336 /* Record all the refs in the basic blocks specified by BLOCKS. */
1337 static void
1340 bitmap blocks;
1341 {
1342 basic_block bb;
1345 {
1347 });
1348 }
1349 \f
1350 /* Dataflow analysis routines. */
1353 /* Create reg-def chains for basic block BB. These are a list of
1354 definitions for each register. */
1355 static void
1358 basic_block bb;
1359 {
1360 rtx insn;
1362 /* Perhaps the defs should be sorted using a depth first search
1363 of the CFG (or possibly a breadth first search). We currently
1364 scan the basic blocks in reverse order so that the first defs
1365 appear at the start of the chain. */
1369 {
1377 {
1380 /* Don't add ref's to the chain two times. I.e. only add
1381 new refs. XXX the same could be done by testing if the current
1382 insn is a modified (or a new) one. This would be faster. */
1388 }
1389 }
1390 }
1393 /* Create reg-def chains for each basic block within BLOCKS. These
1394 are a list of definitions for each register. */
1395 static void
1398 bitmap blocks;
1399 {
1400 basic_block bb;
1403 {
1405 });
1406 }
1409 /* Create reg-use chains for basic block BB. These are a list of uses
1410 for each register. */
1411 static void
1414 basic_block bb;
1415 {
1416 rtx insn;
1418 /* Scan in forward order so that the last uses appear at the
1419 start of the chain. */
1423 {
1431 {
1434 /* Don't add ref's to the chain two times. I.e. only add
1435 new refs. XXX the same could be done by testing if the current
1436 insn is a modified (or a new) one. This would be faster. */
1442 }
1443 }
1444 }
1447 /* Create reg-use chains for each basic block within BLOCKS. These
1448 are a list of uses for each register. */
1449 static void
1452 bitmap blocks;
1453 {
1454 basic_block bb;
1457 {
1459 });
1460 }
1463 /* Create def-use chains from reaching use bitmaps for basic block BB. */
1464 static void
1467 basic_block bb;
1468 bitmap ru;
1469 {
1471 rtx insn;
1475 /* For each def in BB create a linked list (chain) of uses
1476 reached from the def. */
1479 {
1487 /* For each def in insn... */
1489 {
1495 /* While the reg-use chains are not essential, it
1496 is _much_ faster to search these short lists rather
1497 than all the reaching uses, especially for large functions. */
1500 {
1504 {
1509 }
1510 }
1511 }
1513 /* For each use in insn... */
1515 {
1518 }
1519 }
1520 }
1523 /* Create def-use chains from reaching use bitmaps for basic blocks
1524 in BLOCKS. */
1525 static void
1528 bitmap blocks;
1529 {
1530 bitmap ru;
1531 basic_block bb;
1536 {
1538 });
1541 }
1544 /* Create use-def chains from reaching def bitmaps for basic block BB. */
1545 static void
1548 basic_block bb;
1549 {
1552 rtx insn;
1556 /* For each use in BB create a linked list (chain) of defs
1557 that reach the use. */
1560 {
1568 /* For each use in insn... */
1570 {
1576 /* Has regno been defined in this BB yet? If so, use
1577 the last def as the single entry for the use-def
1578 chain for this use. Otherwise, we need to add all
1579 the defs using this regno that reach the start of
1580 this BB. */
1582 {
1585 }
1586 else
1587 {
1588 /* While the reg-def chains are not essential, it is
1589 _much_ faster to search these short lists rather than
1590 all the reaching defs, especially for large
1591 functions. */
1594 {
1598 {
1601 }
1602 }
1603 }
1604 }
1607 /* For each def in insn...record the last def of each reg. */
1609 {
1614 }
1615 }
1616 }
1619 /* Create use-def chains from reaching def bitmaps for basic blocks
1620 within BLOCKS. */
1621 static void
1624 bitmap blocks;
1625 {
1626 basic_block bb;
1629 {
1631 });
1632 }
1633 \f
1636 static void
1642 {
1644 }
1645 static void
1651 {
1653 }
1655 static void
1661 {
1663 }
1666 /* Compute local reaching def info for basic block BB. */
1667 static void
1670 basic_block bb;
1671 {
1673 rtx insn;
1677 {
1685 {
1692 {
1695 /* Add all defs of this reg to the set of kills. This
1696 is greedy since many of these defs will not actually
1697 be killed by this BB but it keeps things a lot
1698 simpler. */
1701 /* Zap from the set of gens for this BB. */
1703 }
1706 }
1707 }
1710 }
1713 /* Compute local reaching def info for each basic block within BLOCKS. */
1714 static void
1717 bitmap blocks;
1718 {
1719 basic_block bb;
1722 {
1724 });
1725 }
1728 /* Compute local reaching use (upward exposed use) info for basic
1729 block BB. */
1730 static void
1733 basic_block bb;
1734 {
1735 /* This is much more tricky than computing reaching defs. With
1736 reaching defs, defs get killed by other defs. With upwards
1737 exposed uses, these get killed by defs with the same regno. */
1740 rtx insn;
1745 {
1754 {
1760 {
1763 /* Add all uses of this reg to the set of kills. This
1764 is greedy since many of these uses will not actually
1765 be killed by this BB but it keeps things a lot
1766 simpler. */
1769 /* Zap from the set of gens for this BB. */
1771 }
1772 }
1775 {
1777 /* Add use to set of gens in this BB. */
1779 }
1780 }
1782 }
1785 /* Compute local reaching use (upward exposed use) info for each basic
1786 block within BLOCKS. */
1787 static void
1790 bitmap blocks;
1791 {
1792 basic_block bb;
1795 {
1797 });
1798 }
1801 /* Compute local live variable info for basic block BB. */
1802 static void
1805 basic_block bb;
1806 {
1808 rtx insn;
1812 {
1820 {
1824 /* Add def to set of defs in this BB. */
1828 }
1831 {
1833 /* Add use to set of uses in this BB. */
1835 }
1836 }
1838 }
1841 /* Compute local live variable info for each basic block within BLOCKS. */
1842 static void
1845 bitmap blocks;
1846 {
1847 basic_block bb;
1850 {
1852 });
1853 }
1856 /* Compute register info: lifetime, bb, and number of defs and uses
1857 for basic block BB. */
1858 static void
1861 basic_block bb;
1862 bitmap live;
1863 {
1866 rtx insn;
1872 {
1881 {
1885 /* Kill this register. */
1888 }
1891 {
1895 /* This register is now live. */
1898 }
1900 /* Increment lifetimes of all live registers. */
1902 {
1904 });
1905 }
1906 }
1909 /* Compute register info: lifetime, bb, and number of defs and uses. */
1910 static void
1913 bitmap blocks;
1914 {
1915 basic_block bb;
1916 bitmap live;
1921 {
1923 });
1926 }
1929 /* Assign LUIDs for BB. */
1930 static int
1933 basic_block bb;
1934 {
1935 rtx insn;
1938 /* The LUIDs are monotonically increasing for each basic block. */
1941 {
1948 }
1950 }
1953 /* Assign LUIDs for each basic block within BLOCKS. */
1954 static int
1957 bitmap blocks;
1958 {
1959 basic_block bb;
1963 {
1965 });
1967 }
1969 /* Perform dataflow analysis using existing DF structure for blocks
1970 within BLOCKS. If BLOCKS is zero, use all basic blocks in the CFG. */
1971 static void
1974 bitmap blocks;
1977 {
1981 basic_block bb;
2002 {
2004 /* More fine grained incremental dataflow analysis would be
2005 nice. For now recompute the whole shebang for the
2006 modified blocks. */
2007 #if 0
2009 #endif
2010 /* All the def-use, use-def chains can be potentially
2011 modified by changes in one block. The size of the
2012 bitmaps can also change. */
2013 }
2014 else
2015 {
2016 /* Scan the function for all register defs and uses. */
2020 /* Link all the new defs and uses to the insns. */
2022 }
2024 /* Allocate the bitmaps now the total number of defs and uses are
2025 known. If the number of defs or uses have changed, then
2026 these bitmaps need to be reallocated. */
2029 /* Set the LUIDs for each specified basic block. */
2032 /* Recreate reg-def and reg-use chains from scratch so that first
2033 def is at the head of the reg-def chain and the last use is at
2034 the head of the reg-use chain. This is only important for
2035 regs local to a basic block as it speeds up searching. */
2037 {
2039 }
2042 {
2044 }
2056 {
2060 }
2062 {
2063 /* Compute the sets of gens and kills for the defs of each bb. */
2065 {
2071 {
2076 }
2084 }
2085 }
2088 {
2089 /* Create use-def chains. */
2094 }
2097 {
2098 /* Compute the sets of gens and kills for the upwards exposed
2099 uses in each bb. */
2101 {
2107 {
2112 }
2120 }
2121 }
2124 {
2125 /* Create def-use chains. */
2130 }
2132 /* Free up bitmaps that are no longer required. */
2137 {
2138 /* Compute the sets of defs and uses of live variables. */
2140 {
2146 {
2151 }
2159 }
2160 }
2163 {
2165 }
2172 }
2175 /* Initialize dataflow analysis. */
2178 {
2183 /* Squirrel away a global for debugging. */
2187 }
2190 /* Start queuing refs. */
2191 static int
2194 {
2197 /* ???? Perhaps we should save current obstack state so that we can
2198 unwind it. */
2200 }
2203 /* Process queued refs. */
2204 static int
2207 {
2210 /* Build new insn-def chains. */
2212 {
2216 /* Add def to head of def list for INSN. */
2219 }
2221 /* Build new insn-use chains. */
2223 {
2227 /* Add use to head of use list for INSN. */
2230 }
2232 }
2235 /* Update refs for basic block BB. */
2236 static int
2239 basic_block bb;
2240 {
2241 rtx insn;
2244 /* While we have to scan the chain of insns for this BB, we don't
2245 need to allocate and queue a long chain of BB/INSN pairs. Using
2246 a bitmap for insns_modified saves memory and avoids queuing
2247 duplicates. */
2250 {
2256 {
2257 /* Delete any allocated refs of this insn. MPH, FIXME. */
2260 /* Scan the insn for refs. */
2263 count++;
2264 }
2267 }
2269 }
2272 /* Process all the modified/deleted insns that were queued. */
2273 static int
2276 {
2277 basic_block bb;
2286 {
2288 });
2292 }
2295 /* Return nonzero if any of the requested blocks in the bitmap
2296 BLOCKS have been modified. */
2297 static int
2300 bitmap blocks;
2301 {
2303 basic_block bb;
2311 {
2314 }
2317 }
2320 /* Analyse dataflow info for the basic blocks specified by the bitmap
2321 BLOCKS, or for the whole CFG if BLOCKS is zero, or just for the
2322 modified blocks if BLOCKS is -1. */
2323 int
2326 bitmap blocks;
2328 {
2331 /* We could deal with additional basic blocks being created by
2332 rescanning everything again. */
2338 {
2340 {
2342 {
2343 /* Recompute everything from scratch. */
2345 }
2346 /* Allocate and initialize data structures. */
2350 }
2351 else
2352 {
2362 }
2363 }
2365 }
2368 /* Free all the dataflow info and the DF structure. */
2369 void
2372 {
2375 }
2378 /* Unlink INSN from its reference information. */
2379 static void
2382 basic_block bb ATTRIBUTE_UNUSED;
2383 rtx insn;
2384 {
2390 /* Unlink all refs defined by this insn. */
2394 /* Unlink all refs used by this insn. */
2400 }
2403 #if 0
2404 /* Unlink all the insns within BB from their reference information. */
2405 static void
2408 basic_block bb;
2409 {
2410 rtx insn;
2412 /* Scan the block an insn at a time from beginning to end. */
2414 {
2416 {
2417 /* Unlink refs for INSN. */
2419 }
2422 }
2423 }
2426 /* Unlink all the refs in the basic blocks specified by BLOCKS.
2427 Not currently used. */
2428 static void
2431 bitmap blocks;
2432 {
2433 basic_block bb;
2436 {
2438 {
2440 });
2441 }
2442 else
2443 {
2446 }
2447 }
2448 #endif
2449 \f
2450 /* Functions to modify insns. */
2453 /* Delete INSN and all its reference information. */
2454 rtx
2457 basic_block bb ATTRIBUTE_UNUSED;
2458 rtx insn;
2459 {
2460 /* If the insn is a jump, we should perhaps call delete_insn to
2461 handle the JUMP_LABEL? */
2463 /* We should not be deleting the NOTE_INSN_BASIC_BLOCK or label. */
2467 /* Delete the insn. */
2473 }
2476 /* Mark that INSN within BB may have changed (created/modified/deleted).
2477 This may be called multiple times for the same insn. There is no
2478 harm calling this function if the insn wasn't changed; it will just
2479 slow down the rescanning of refs. */
2480 void
2483 basic_block bb;
2484 rtx insn;
2485 {
2495 /* For incremental updating on the fly, perhaps we could make a copy
2496 of all the refs of the original insn and turn them into
2497 anti-refs. When df_refs_update finds these anti-refs, it annihilates
2498 the original refs. If validate_change fails then these anti-refs
2499 will just get ignored. */
2500 }
2504 rtx match;
2505 rtx replacement;
2506 rtx insn;
2511 /* Replace mem pointed to by PX with its associated pseudo register.
2512 DATA is actually a pointer to a structure describing the
2513 instruction currently being scanned and the MEM we are currently
2514 replacing. */
2515 static int
2519 {
2527 {
2532 /* We're not interested in the MEM associated with a
2533 CONST_DOUBLE, so there's no need to traverse into one. */
2537 /* This is not a MEM. */
2539 }
2542 /* This is not the MEM we are currently replacing. */
2545 /* Actually replace the MEM. */
2550 }
2553 int
2556 basic_block bb;
2557 rtx insn;
2558 rtx mem;
2559 rtx reg;
2560 {
2561 replace_args args;
2568 /* Search and replace all matching mems within insn. */
2574 /* ???? FIXME. We may have a new def or one or more new uses of REG
2575 in INSN. REG should be a new pseudo so it won't affect the
2576 dataflow information that we currently have. We should add
2577 the new uses and defs to INSN and then recreate the chains
2578 when df_analyse is called. */
2580 }
2583 /* Replace one register with another. Called through for_each_rtx; PX
2584 points to the rtx being scanned. DATA is actually a pointer to a
2585 structure of arguments. */
2586 static int
2590 {
2598 {
2601 }
2604 }
2607 /* Replace the reg within every ref on CHAIN that is within the set
2608 BLOCKS of basic blocks with NEWREG. Also update the regs within
2609 REG_NOTES. */
2610 void
2613 bitmap blocks;
2615 rtx oldreg;
2616 rtx newreg;
2617 {
2619 replace_args args;
2629 {
2637 {
2640 /* Replace occurrences of the reg within the REG_NOTES. */
2644 {
2647 }
2648 }
2649 else
2650 {
2651 /* Temporary check to ensure that we have a grip on which
2652 regs should be replaced. */
2654 }
2655 }
2656 }
2659 /* Replace all occurrences of register OLDREG with register NEWREG in
2660 blocks defined by bitmap BLOCKS. This also replaces occurrences of
2661 OLDREG in the REG_NOTES but only for insns containing OLDREG. This
2662 routine expects the reg-use and reg-def chains to be valid. */
2663 int
2666 bitmap blocks;
2667 rtx oldreg;
2668 rtx newreg;
2669 {
2675 }
2678 /* Try replacing the reg within REF with NEWREG. Do not modify
2679 def-use/use-def chains. */
2680 int
2684 rtx oldreg;
2685 rtx newreg;
2686 {
2687 /* Check that insn was deleted by being converted into a NOTE. If
2688 so ignore this insn. */
2700 }
2706 basic_block bb;
2707 rtx def_insn;
2708 rtx use_insn;
2710 {
2725 /* The USE no longer exists. */
2730 /* The DEF requires shifting so remove it from DEF_INSN
2731 and add it to USE_INSN by reusing LINK. */
2738 #if 0
2743 #endif
2747 }
2750 /* Record df between FIRST_INSN and LAST_INSN inclusive. All new
2751 insns must be processed by this routine. */
2752 static void
2755 basic_block bb;
2756 rtx first_insn;
2757 rtx last_insn;
2758 {
2759 rtx insn;
2762 {
2765 /* A non-const call should not have slipped through the net. If
2766 it does, we need to create a new basic block. Ouch. The
2767 same applies for a label. */
2782 }
2783 }
2786 /* Emit PATTERN before INSN within BB. */
2787 rtx
2790 rtx pattern;
2791 basic_block bb;
2792 rtx insn;
2793 {
2794 rtx ret_insn;
2797 /* We should not be inserting before the start of the block. */
2806 }
2809 /* Emit PATTERN after INSN within BB. */
2810 rtx
2813 rtx pattern;
2814 basic_block bb;
2815 rtx insn;
2816 {
2817 rtx ret_insn;
2825 }
2828 /* Emit jump PATTERN after INSN within BB. */
2829 rtx
2832 rtx pattern;
2833 basic_block bb;
2834 rtx insn;
2835 {
2836 rtx ret_insn;
2844 }
2847 /* Move INSN within BB before BEFORE_INSN within BEFORE_BB.
2849 This function should only be used to move loop invariant insns
2850 out of a loop where it has been proven that the def-use info
2851 will still be valid. */
2852 rtx
2855 basic_block bb;
2856 rtx insn;
2857 basic_block before_bb;
2858 rtx before_insn;
2859 {
2868 /* Change bb for all df defined and used by this insn. */
2874 /* The lifetimes of the registers used in this insn will be reduced
2875 while the lifetimes of the registers defined in this insn
2876 are likely to be increased. */
2878 /* ???? Perhaps all the insns moved should be stored on a list
2879 which df_analyse removes when it recalculates data flow. */
2882 }
2883 \f
2884 /* Functions to query dataflow information. */
2887 int
2890 basic_block bb ATTRIBUTE_UNUSED;
2891 rtx insn;
2893 {
2900 {
2905 }
2908 }
2911 static int
2915 {
2918 /* Follow def-use chain to find all the uses of this def. */
2920 {
2924 /* Follow use-def chain to check all the defs for this use. */
2928 }
2930 }
2933 int
2936 basic_block bb ATTRIBUTE_UNUSED;
2937 rtx insn;
2938 {
2945 {
2950 }
2953 }
2956 /* Return nonzero if all DF dominates all the uses within the bitmap
2957 BLOCKS. */
2958 static int
2962 bitmap blocks;
2963 {
2966 /* Follow def-use chain to find all the uses of this def. */
2968 {
2972 /* Only worry about the uses within BLOCKS. For example,
2973 consider a register defined within a loop that is live at the
2974 loop exits. */
2976 {
2977 /* Follow use-def chain to check all the defs for this use. */
2981 }
2982 }
2984 }
2987 /* Return nonzero if all the defs of INSN within BB dominates
2988 all the corresponding uses. */
2989 int
2992 basic_block bb ATTRIBUTE_UNUSED;
2993 rtx insn;
2994 bitmap blocks;
2995 {
3002 {
3005 /* Only consider the defs within BLOCKS. */
3009 }
3011 }
3014 /* Return the basic block that REG referenced in or NULL if referenced
3015 in multiple basic blocks. */
3016 basic_block
3020 {
3028 /* Compare blocks of first def and last use. ???? FIXME. What if
3029 the reg-def and reg-use lists are not correctly ordered. */
3031 }
3034 /* Return nonzero if REG used in multiple basic blocks. */
3035 int
3038 rtx reg;
3039 {
3041 }
3044 /* Return total lifetime (in insns) of REG. */
3045 int
3048 rtx reg;
3049 {
3051 }
3054 /* Return nonzero if REG live at start of BB. */
3055 int
3058 basic_block bb;
3059 rtx reg;
3060 {
3063 #ifdef ENABLE_CHECKING
3066 #endif
3069 }
3072 /* Return nonzero if REG live at end of BB. */
3073 int
3076 basic_block bb;
3077 rtx reg;
3078 {
3081 #ifdef ENABLE_CHECKING
3084 #endif
3087 }
3090 /* Return -1 if life of REG1 before life of REG2, 1 if life of REG1
3091 after life of REG2, or 0, if the lives overlap. */
3092 int
3095 basic_block bb;
3096 rtx reg1;
3097 rtx reg2;
3098 {
3107 /* The regs must be local to BB. */
3127 }
3130 /* Return last use of REGNO within BB. */
3134 basic_block bb ATTRIBUTE_UNUSED;
3136 {
3139 /* This assumes that the reg-use list is ordered such that for any
3140 BB, the last use is found first. However, since the BBs are not
3141 ordered, the first use in the chain is not necessarily the last
3142 use in the function. */
3144 {
3149 }
3151 }
3154 /* Return first def of REGNO within BB. */
3158 basic_block bb ATTRIBUTE_UNUSED;
3160 {
3163 /* This assumes that the reg-def list is ordered such that for any
3164 BB, the first def is found first. However, since the BBs are not
3165 ordered, the first def in the chain is not necessarily the first
3166 def in the function. */
3168 {
3173 }
3175 }
3178 /* Return first use of REGNO inside INSN within BB. */
3182 basic_block bb ATTRIBUTE_UNUSED;
3183 rtx insn;
3185 {
3192 {
3197 }
3200 }
3203 /* Return first def of REGNO inside INSN within BB. */
3207 basic_block bb ATTRIBUTE_UNUSED;
3208 rtx insn;
3210 {
3217 {
3222 }
3225 }
3228 /* Return insn using REG if the BB contains only a single
3229 use and def of REG. */
3230 rtx
3233 basic_block bb;
3234 rtx insn;
3235 rtx reg;
3236 {
3253 /* Check if def is dead. */
3257 /* Check for multiple uses. */
3262 }
3263 \f
3264 /* Functions for debugging/dumping dataflow information. */
3267 /* Dump a def-use or use-def chain for REF to FILE. */
3268 static void
3272 {
3275 {
3279 }
3281 }
3283 static void
3287 {
3290 {
3295 }
3297 }
3299 /* Dump dataflow info. */
3300 void
3305 {
3307 basic_block bb;
3317 {
3318 basic_block bb;
3322 {
3336 }
3337 }
3340 {
3343 {
3345 {
3355 }
3356 }
3357 }
3360 {
3363 {
3377 }
3378 }
3381 {
3384 {
3386 {
3396 }
3397 }
3398 }
3401 {
3404 {
3418 }
3419 }
3422 {
3427 {
3432 {
3435 {
3440 else
3442 }
3444 {
3446 }
3449 {
3455 }
3458 {
3464 }
3467 }
3468 }
3469 }
3471 }
3474 void
3477 rtx insn;
3479 {
3491 else
3500 }
3502 void
3505 rtx insn;
3507 {
3519 else
3528 }
3530 static void
3535 {
3545 }
3548 static void
3553 {
3564 }
3567 void
3569 rtx insn;
3570 {
3573 }
3576 void
3578 rtx reg;
3579 {
3581 }
3584 void
3587 {
3589 }
3592 void
3595 {
3597 }
3600 void
3603 {
3605 }
3608 void
3611 {
3613 }
3616 void
3619 {
3622 }
3624 /* Hybrid search algorithm from "Implementation Techniques for
3625 Efficient Data-Flow Analysis of Large Programs". */
3626 static void
3629 data)
3630 basic_block block;
3634 transfer_function_bitmap transfun;
3635 sbitmap visited;
3636 sbitmap pending;
3638 {
3641 edge e;
3645 {
3647 {
3648 /* Calculate <conf_op> of predecessor_outs */
3651 {
3655 {
3662 }
3663 }
3664 }
3665 else
3666 {
3667 /* Calculate <conf_op> of successor ins */
3670 {
3674 {
3681 }
3682 }
3683 }
3684 /* Common part */
3688 {
3690 {
3692 {
3696 }
3697 }
3698 else
3699 {
3701 {
3705 }
3706 }
3707 }
3708 }
3710 {
3712 {
3718 data);
3719 }
3720 }
3721 else
3722 {
3724 {
3730 data);
3731 }
3732 }
3733 }
3736 /* Hybrid search for sbitmaps, rather than bitmaps. */
3737 static void
3740 data)
3741 basic_block block;
3745 transfer_function_sbitmap transfun;
3746 sbitmap visited;
3747 sbitmap pending;
3749 {
3752 edge e;
3756 {
3758 {
3759 /* Calculate <conf_op> of predecessor_outs */
3762 {
3766 {
3773 }
3774 }
3775 }
3776 else
3777 {
3778 /* Calculate <conf_op> of successor ins */
3781 {
3785 {
3792 }
3793 }
3794 }
3795 /* Common part */
3799 {
3801 {
3803 {
3807 }
3808 }
3809 else
3810 {
3812 {
3816 }
3817 }
3818 }
3819 }
3821 {
3823 {
3829 data);
3830 }
3831 }
3832 else
3833 {
3835 {
3841 data);
3842 }
3843 }
3844 }
3849 /* gen = GEN set.
3850 kill = KILL set.
3851 in, out = Filled in by function.
3852 blocks = Blocks to analyze.
3853 dir = Dataflow direction.
3854 conf_op = Confluence operation.
3855 transfun = Transfer function.
3856 order = Order to iterate in. (Should map block numbers -> order)
3857 data = Whatever you want. It's passed to the transfer function.
3859 This function will perform iterative bitvector dataflow, producing
3860 the in and out sets. Even if you only want to perform it for a
3861 small number of blocks, the vectors for in and out must be large
3862 enough for *all* blocks, because changing one block might affect
3863 others. However, it'll only put what you say to analyze on the
3864 initial worklist.
3866 For forward problems, you probably want to pass in a mapping of
3867 block number to rc_order (like df->inverse_rc_map).
3868 */
3869 void
3873 bitmap blocks;
3876 transfer_function_sbitmap transfun;
3879 {
3881 fibheap_t worklist;
3882 basic_block bb;
3890 {
3895 else
3897 });
3899 {
3901 {
3907 }
3909 {
3911 {
3913 });
3915 }
3916 else
3917 {
3919 }
3920 }
3924 }
3926 /* Exactly the same as iterative_dataflow_sbitmap, except it works on
3927 bitmaps instead */
3928 void
3932 bitmap blocks;
3935 transfer_function_bitmap transfun;
3938 {
3940 fibheap_t worklist;
3941 basic_block bb;
3949 {
3954 else
3956 });
3958 {
3960 {
3966 }
3968 {
3970 {
3972 });
3974 }
3975 else
3976 {
3978 }
3979 }
3983 }